This invention relates to a method of operating a set of devices and to a real world representation system comprising a set of devices. In particular this invention relates to operating the devices to provide a real world experience.
In any communication system or multimedia system, a predetermined event, such as the receipt of an e-mail or loading of a CD results in an indication or a change in the information conveyed to a user. For example, when a telephone receives an incoming call it produces an audible ringing. However, such an indication conveys limited information to the user and is provided by just the device concerned.
It is an object of the present Invention to provide an improved method of operating a set of devices.
According to a first aspect of the invention, there is provided a method of operating a set of devices, said set for providing a real world experience in accordance with a real world description in the form of an instruction set of a markup language, comprising operating said set of devices to provide a real world experience in response to a predetermined event.
According to a second aspect of the invention, there is provided a real world representation system comprising a set of devices, said set for providing a real world experience in accordance with a real world description in the form of an instruction set of a markup language, and said devices being operated to provide a real world experience in response to a predetermined event.
Owing to the invention the user is provided with a real world experience in response to a predetermined event. The ambient environment surrounding the user is employed to convey the experience to the user via at least one of the user's natural senses.
Advantageously, the experience may complement the event and/or be characteristic of the event thereby identifying the event as a particular type and/or specific event.
The event may comprise the receipt of an electronic communication such as an e-mail, a telephone call or an S.M.S. message. Advantageously, the real world experience may identify the source of the electronic communication by having elements characteristic of a particular source.
The real world description may be transmitted to the system as part of the event or retrieved from a local store.
The event may comprise an operation of an electronic device such as the loading of a CD on a hi-fi.
Embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which:
In addition to the display device 10, the walls 18 and floor 20 are provided with display functionality. This can be achieved either by the walls 18 and floor 20 being composed of fabric display material, or a centered ceiling projector can illuminate the visible portions of the walls 18 and the floor 20. It is also feasible to back light the walls 18 if the environment allows it.
The system of
The telephone 17 shown in
The PC 13 includes receiving means for receiving an electronic communication in the form of an e-mail. The system can detect an unopened e-mail and operate the set of devices accordingly. In addition, the PC includes a display, a processor and a data storage device.
Examples of predetermined events and the consequential operation of the system of
In a first example, a caller makes a telephone call to the telephone 17 of the users system. The telephone 17 receives this call and recognizes the source of the call by identifying the caller's telephone number as one which has previously been stored thereon. The receipt of the call constitutes the aforementioned predetermined event. Each stored telephone number, corresponding to a caller known to the user, has an associated and pre-defined real world description in the form of an instruction set of a markup language. The telephone is arranged to receive the real world description from a local store such as an integral optical data storage device. Having recognized this particular caller, the telephone 17 transmits the associated description to the other devices in the system.
This description is distributed amongst the devices. Each markup language enabled device operates in principally the same manner. For example, the lighting device 14 has input means for receiving the real-world description in the form of an instruction set of a markup language, the input means including part of a distributed browser that interprets the instructions of the instruction set. The portion of the browser in the input means communicates with adjusting means that is arranged to adjust one or more parameters of the lighting device 14. In this first example, the caller is a friend of the user and is a pilot. The associated pre-defined description decided by the user reads <SKY>, <BRIGHT>, <AEROPLANE> and the part of the browser in the input means interprets this into specific instructions relating to the colour tones and luminance level for the adjusting means to adjust their levels accordingly. Therefore, the likely colour tone would be a sky blue and the light level would be high. The browser interprets instructions of a general type to generate specific parameter adjustments. The experience identifies the source of the communication.
The description is received by all of the other parts of the distributed browser in each of the other devices in the real-world representation system. Each device interprets the instructions and adjusts its parameter configuration accordingly. For example, the telephone 17 may make an audible ringing sound in addition to effects created by the other devices. The greater number of enabled devices that are present in a particular environment the more realistic the end result will be. In particular the operability of the walls 18 and floor 20 as display devices will determine how immersed in the real world representation the user feels.
There are many possible alternative set-ups for the system to provide a real world experience in response to an incoming telephone call. For example, the telephone 17 need not make an audible ringing sound when it receives a call but instead, the real world experience identifies the event as a particular type of event, an incoming telephone call in this case. This may be achieved by providing special lighting effects around the telephone 17 for example. The real world experience can equally identify the event as a specific event, for example by identifying who is calling.
In the case where the telephone 17 does not recognize the source of the call, for example where the call is from a telephone number not previously stored, the real world experience may indicate this by including a particular sound. However, it is possible for a caller to send a real world description in the form of an instruction set of a markup language via the telephone 17. This allows, for example, the caller to send a “signature” description which is characteristic of the caller, to be rendered on the system on receipt of the call instead of receiving the real world description from the local store.
Real world descriptions in the form of an instruction set of a markup language can be easily downloaded from an external source and stored on the local store for later use. Such descriptions can include tailored signatures for association with known callers for example. In this way, the user can build up a personal palette of signature descriptions.
The telephone 17 may also comprise answer phone functionality thus allowing callers to record a message and/or a real world description in the form of an instruction set. This can be achieved by a caller recording a URL on the answer phone that points to an instruction set. Then the user can render a real world experience in accordance with the description via the URL at a later time.
Alternatively, telephone calls can be received on a mobile telephone device (not shown). The mobile telephone transmits a real world description either to the system of
In a second example, a sender sends an e-mail to the user which is received by the PC 13. The receipt of the e-mail constitutes the aforementioned predetermined event. The PC 13 recognizes the sender's address as a pre-defined trusted source. The e-mail includes a real world description in the form of an instruction set of a markup language. Having recognized this particular sender as a trusted source and received the real world description from the e-mail, the PC 13 transmits the description to the other devices in the system. As before, the description is distributed amongst the devices. In this second example, the sender is a friend of the user and is on a camping holiday in the forest. The real world description sent by the sender is indicative of the local ambience being experienced in the forest and reads <FOREST>, <SUMMER>, <EVENING>. The distributed browser interprets this and operates the set of devices accordingly. This allows the user to experience the same ambience as his friend from the comfort of his couch.
As an alternative set-up, the PC 13 may only transmit the description to the other devices in the system when the user opens the e-mail. This could be preceded by a subtle change in the ambience to indicate that a new e-mail has arrived. The sender's identity may also be indicated by this change in experience. The real world description need not be included as part of the e-mail but instead, as with the first example, it could be received from a local store.
As well as the PC 13 and the telephone 17, other electronic devices can be arranged to receive electronic communications such as set-top boxes and remote control devices (not shown in
In the case of electronic communications such as incoming telephone calls and e-mails, careful consideration should be given when designing the system to prevent misuse given that the experiences may be rendered without the prior explicit consent from the user.
In a third example, the user loads a CD onto the PC 13 which recognizes this operation of an electronic device as a predetermined event. This operation has an associated real world description in the form of an instruction set of a markup language which has been previously defined by the user. The PC is arranged to receive the real world description from a local store such as an integral optical data storage device. Having recognized this particular operation, the PC 13 transmits the associated description to the other devices in the system. The associated description reads <ASTRO>, <STARS>, <PC> and the distributed browser interprets this into specific instructions to operate each of the devices. The “ASTRO” part of the description relates to a space-themed experience pre-selected by the user who may dictate that this theme is also applied to all other user operations associated with the PC. The devices are operated to provide a real world experience in response to the predetermined event. For example, the audio speakers 12 output sound having a space theme in response to the loading of the CD onto the PC 13.
In a further example of an operation of an electronic device, an alarm clock (not shown) wakes up the user by providing a real world experience instead of just an audible sound output associated with a conventional alarm clock. The alarm clock transmits a real world description to the other devices in the system. The devices render a real world experience in accordance with this description in a similar manner to the aforementioned examples.
Although the above examples describe the system as having a distributed browser for interpreting the received real world description, it is envisaged that the description can be read at a local server, which can be a dedicated device or could be contained within the capability of a device that nominally has a different purpose. In this case a browser or operating system present on the local server interprets the instructions of the real-world description and generates specific parameter adjustments for communicating to the relevant device. In this way devices currently available can be used without the requirement that they be modified or purpose built for use in the real world representation system.
The flowchart of
A user can operate the system in a relatively simple manner from a user interface such as a remote control, although equally an enabled PDA or other mobile terminal could be employed. The user can select an environment that they wish to be immersed in from preselected total descriptions or create a new environment from pre- or user defined variables. Such a total description may, for example, be <CHINESE RESTAURANTS>, which real world experience is then rendered by the devices in the system. The real worlds generated can be fantasy environments or they can be realistic.
The user can also operate the user interface to set limits on the operation of the devices in the system. For example, if the user wishes to set the volume of those devices with an audio capability to a specific range or set an upper limit on the volume then they can do so via the user interface. This prevents experiences becoming unpleasant for the user. The level of the light and the rate of any change in light intensity are also things that the user can control. All of the parameters of the system can be user defined.
The description of the real world experiences is provided by a markup language that communicates a description of physical environments and the objects within them, their relationship to the user, each other and to the physical space. Within a location that is enabled to produce a real world experience, the instruction set of the markup language is interpreted by a device or devices to render the experience. Each device that is enabled contains a component that interprets the instruction set to the best of its capability.
The language contains a wide range of states that can be rendered by the devices in a real world representation system. Such states relate to:
Any information that relates to a physical experience can be expressed in this markup language as long as the browser or local server is arranged to interpret the description. To create instruction sets in the markup language an author can write directly into the language or a computer program for authoring an instruction set can be used. The authoring program can take data input in the form of, for example, text or video and can generate a set of instructions comprising a subset of the markup language that when passed to a real-world representation system will allow the devices in that system to render the experience that corresponds to that of the text or video.
The language is XML compliant, XML being a meta-language that describes the standard structure for new markup languages.
Number | Date | Country | Kind |
---|---|---|---|
0211899.0 | May 2002 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB03/02070 | 5/15/2003 | WO | 11/18/2004 |